Metamorphic Reactions and Protoliths of Metamorphic Rocks Development of Metamorphic Rocks
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Lecture FOUR Metamorphic Reactions and Protoliths of Metamorphic Rocks Development of Metamorphic Rocks The yielded metamorphic rocks, with specific mineral composition and textures is a function of: Protolith nature i.e: whole rock chemistry (pelitic (Argillaceous), semipelitic, calcareous (limestone and dolomite), mafic-ultramafic, basic igneous, granitic, Mn-rich sediments, ironstone, laterites... etc.) P-T-X conditions (the intensity of temperature and the intensity and type of pressure (simple compressed or twisted and broken) influence and the presence or absence of fluids and their chemistry during metamorphism) Time (how long the rock subjected to HT and HP?. By which the grain size was evolved, and the reactions were proceed) Metamorphic Rocks components and development A metamorphic rock consists of individual grains of several solid minerals and a network of grain boundaries, which at the time of metamorphism may have held an aqueous fluid, providing pathways for transport through the rock. garnet Omphacite garnet Development of Metamorphic minerals For a new mineral to appear by a chemical reaction, a number of processes have to operate in concern: Nucleation: nuclei (embryo crystals) of the new mineral appear Interface reactions - dissolution: reactant minerals break down, their chemical constituents going into solution Interface reactions - growth: material is added onto the nuclei to build larger crystals Mass transfer: material is transported through the rock from sites of breakdown to sites of growth Nucleation, Mineral growth and Grain size -Completed reaction produces an amount of product (mineral phases). The microstructure, will depend on the relative rates of nucleation and growth of minerals - Grain size in a metamorphic rocks is a function in: - Intensity of P-T conditions, - nuclation rate, and -Time interval of metamorphism -Coarse-grained rocks are the product of long sustained metamorphic conditions (possibly over millions of years) at HT and HP (e.g. in high grade regional metamorphic rocks) -Fine-grained rocks are products of LP, LT, in some cases, short reaction time (e.g. in contact metamorphiic rocks) Metamorphic Reactions and P-T path - With increasing P-T conditions, metamorphic reaction toke place (e.g. burial effect) until the maximum pressure and temperature (peak condition), then with decreasing the P-T conditions (e.g. uplift) until cooling of the rock. This is known as Metamorphic P-T path - The P-T path include three segments: Prograde segment: With increasing the P-T conditions (such as burial effect) Peak segment: at maximum P- T conditions (at the summit metamorphic conditions) Retrograde segment: With decreasing P-T conditions (such as uplift) - The metamorphic P-T can be simple (clockwise or anticlockwise) or complex due to multiphase metamorphism Types of Metamorphic reactions - With either progressing or retrogressing metamorphism, various types of metamorphic reactions are proceeds e.g.: 1- Univarient reactions: reactions that plot as line or curve on the P-T diagram and depend on temperature and pressure only e.g: Al2Si4O10(OH)2 Al2SiO5 + 3 SiO2 + H2O Pyrophyllite Al-silicate + Qtz + fluid Cont. Types of Metamorphic reactions 2- Divarient reactions: reactions occur over wide range of P-T. This because most minerals involved in the reaction exhibit solid solution (e.g garnet, mica, plagioclase); therefore, the reaction boundaries can changed depend on the composition of solid solution. KAl2Si3AlO10(OH)2 + SiO2 = KAlSi3O8 + Al2SiO5 + H2O Ms Qtz Kfs Sill W Cont. Types of Metamorphic reactions 3- Solid-soild reaction: only involve the solid-phases for both reactant and products (with no fluid phases). So reactions involves phase transformation e.g. Calcite aragonite, andalusite sillimanite, graphite diamond Albite jadite + quartz Cont. Types of Metamorphic reactions 4- Dehydration reactions: reactions that liberate H2O. This always occur in the prograde reaction, i.e. with increasing temperature e.g chlorite + muscovite orthoclase + andalusite + H2O 5- Decabonation reaction : reactions that liberate CO2 e.g Calcite + quartz Wallstonite + CO2 Cont. Types of Metamorphic reactions 6- Oxidation-reduction reaction: reactions that involve change the valence state of Fe-Ti oxide phases (Fe+2 and Fe+3) e.g: the breakdown of biotite to K-feldspars and magnetite at high P-T cinditions biotite + O2 K-feldspars + Magnetite + H2O 7- Cation exchange reaction: reaction involves ionic substitution of two or more phases in the system e.g: Fe-garnet + Mg-biotite Fe-biotite + Mg-garnet Protoliths of metamorphic rocks As we discuss, The yielded metamorphic rocks is function of: - Protolith (original rock) nature bulk-rock chemistry - P (pressure)-T (temperature)-X (active fluids) conditions - Time At specific P-T-X conditions, reactions in solid state toke place in the rock and new equilibrated mineral assemblage and corresponding textures are arise, which equivalent to the influence metamorphic conditions. Protoliths of metamorphic rocks The protoliths of the metamorphic rocks could be: -Sedimentary rocks -Shales (Pelitic rocks) -Sandstones (Arenaceous rocks and semipelitic rocks) -Carbonate (Calcareous rocks) -marl rocks - Igneous rocks - Basic igneous rocks (metabasites) - Ultramafic rocks - Intermediate rocks - Acidic rocks - Prior metamorphic rocks Metapelites Shales (Pelites): very fine-grained sedimentary rocks, composed of silicate clay minerals rich in the elements (SiO2, Al2O3, FeO, K2O, Na2O, H2O), beside other minor elements. - Common metamorphic minerals include - Quartz - Feldspars (plagioclase, K-feldspars) - Mica (sericite, muscovite, biotite, chlorite) - garnet, - staurolite, - cordierite, - Al-silicate (andalusite, kyanite, silliminite) - Pyroxene Quartz Orthoclase Perthite Microcline Plagiocalse Chlorite Muscovite Biotite Garnet Group Staurolite Al-silicates Andalusite Kyanite 1. Sillimanite ( C ) Cordierite Orthopyroxene Metacarbonate rocks Limestone and dolomite (Calcareous rocks), composed essentially of calcite (CaCO3), doilomite (CaMg(CO3)2, with minor quartz and clay minerals. If the clay minerals are excess, the rock known as marl - the yielded rocks is known as Marble (mainly calcite) if the calcareous rocks are pure. In case of non-pure calcareous rocks, marble contain silicate minerals such as: wollastonite, grossular-andradite garnet, diopside and tremolite (a) Limestone (fiossiliferous) Calcite (CaCO3) Anthophyllite Metamorphosed sandstone Sandstones (Arenaceous rocks): of variable composition, arenite (wholly quartz), arkose (quartz + feldspars) and graywackes (quartz, lithic fragment and clayey matrix) -Metamorphism of sandstone yield gneisses (quartz + plagioclase + K-feldspars + biotite + granet + Fe-Ti oxides) - Metamorphism of graywackes formed a metamorphic rocks intermediate between metapelites and gneisses) - Arenites yield quartizites Quartz Sandstone Metamorphosed basic igneous rocks Basic rocks including basalts and gabbros, are low silica igneous rocks that contain plagioclase and pyroxene. - Metamorphism of basic igneous rocks yielded metabasites (quartz, plagioclase, amphiboles, garnet, epidotes, chlorite) - If the rock is composed of plagioclase and amphibole, amphibolites term are used - At extreme P-T conditions, Eclogites are formed (garnet + omphacite) CPX: Diopside - Augite Omphacite Tremolite-actinolite Hornblende Glucophane Metamorphosed Ultramafic rocks Ultramafic rocks, Mg-Fe rich silicate minerals (Diopside, Olivine) -When metamorphosed yielded produce serpentinites and talc schists with mineral assemblage include serpentine minerals, talc, enstatite, diopside, anthophyllite, tremolite, hornblende, garnets and chlorite Serpentine Talc.